DE1489665B - Electromedical stimulation current device - Google Patents

Description

The invention relates to an electromedical electrical stimulation device for generating current pulses with a patient circuit, which consists of a series connection of a storage capacitor, Connection devices to a body part to be treated and an electronic discharge control member exists, which controls the discharge of the storage capacitor with the help of control pulses, with a voltage source that is used to charge the storage capacitor via an electronic charge control device, which can be blocked with the help of the control pulses during the discharge period of the storage capacitor, between the first control element and the storage capacitor is connected to the patient circuit, and with a device to generate the control pulses.

Such a stimulation current device is in the older, unpublished German patent 1233 958 has been proposed.

Furthermore, the German Auslegeschrift 1048 643 an electromedical electrical stimulation device known for generating current pulses with a patient circuit, which consists of a series circuit a storage capacitor, connection devices to a part of the body to be treated and an electronic discharge control element, the discharge of the with the help of control pulses Storage capacitor controls. The known device also has a voltage source for charging the Storage capacitor and a device for generating the control pulses.

By the Swiss patent 219 798 is also an electromedical stimulation current device for Generation of current pulses known in the patient circuit in series with the patient to be treated Body part leading connecting devices a pentode tube as an electronic control member is switched.

When used as a dental stimulator, a current pulse is applied to a tooth, usually as a square pulse, of short duration (10 μ sec is a value that in practice is common) and at a current strength (amplitude peak) within a range of, for example 1 to 100 μΑ supplied. These square-wave pulses are intended as a regular pulse train of, for example, one or two impulses per second or as individual impulses at arbitrarily selected times will. In the case of stimulators for other medical purposes, of course other conditions regarding pulse length, intermediate times and amplitude occur.

Since a tooth generally has a very high resistance, a relatively high voltage is usually necessary be to get the desired pulse amplitude; it has been shown in practice that in In some cases voltages up to a few 100 volts are necessary. When using that high Voltages there is a risk that if a component of the system fails, the current will be so large that that the patient is harmed. The invention relates to a device in which this danger is reduced to a minimum.

The object of the present invention is to create an electromedical electrical stimulation device which is essentially the risk of a patient receiving such a large current that he can suffer harm is eliminated.

This task is achieved in an electromedical electrical stimulation device of the type described at the outset solved that the in the charging circuit of the storage capacitor to him in series and parallel to the to a rectifier is arranged on the connecting devices leading to the body part to be treated, that the current-limiting discharge control organ

;. rend, the duration of the control pulses an adjustable

-able electricity, conducts and during the intervening Time intervals is locked and that the charging control device from one in the direction of Storage capacitor conductive diode, which with the help of a blocking device by the control pulses is lockable.

It has been shown that by means of an apparatus designed in this way, the risk of the patient becoming so receives large current that damage can occur, in fact, is completely eliminated.

According to an advantageous development of the electrical stimulation device described above, the The diode transmitting the charging current has its anode via a further diode and a charging control element connected to a voltage that is equal to or less than the cathode voltage of the discharge control element, and the charging controller is during the duration of the control pulses, but not in the Time intervals between the control pulses conductive. It has been found to be advantageous that an electronic Auxiliary control element is influenced by the control pulse in such a way that it affects the control electrode of the discharge control element during the control pulse via a locked between the control pulses Keeps the diode at an adjustable voltage.

The electronic auxiliary control element can during the control pulse of the control electrode of the charging control element give such a voltage that a large current flows through the charge controller.

The discharge control element is advantageously an electron tube in the form of a pentode and that Charge controller an electron tube in the form of a triode or transistor.

In a preferred embodiment, the auxiliary control element is a transistor.

The electrical stimulation device described above is described in detail with reference to the drawing explained in more detail.

F i g. 1 shows a circuit diagram of the output stage as an exemplary embodiment of the stimulation current device described above a dental stimulator, and

F i g. 2 shows a modification of the circuit according to FIG. 1.

The in F i g. 1 has a dental stimulator consisting of an electron tube in the form of a pentode current-generating discharge control element (V 2), the anode of which the anode voltage from a terminal (denoted by +) of a voltage source via a first resistor R 1, an ammeter A, which is via a Switch 51 can be short-circuited, receives a second resistor R 4 and a diode D 2 . The cathode of the discharge control process V 2 is connected to a grounded point; the grid of the electron tube in the form of a pentode receives a voltage that is constant with respect to earth due to the interaction of the resistor R5 and a constant voltage tube V 3, for example a gas discharge tube (neon tube).
Furthermore, the anode of the discharge control

organs V 2 one plate of the storage capacitor C is connected, the other capacitor plate is connected to an electrode terminal labeled UT , which is to be connected to the tooth to be tested and also to be grounded via a rectifier D 3. A second electrode clip B to be connected to the tooth is also grounded.

In order to obtain some bias voltages and auxiliary voltages according to the description below, which are negative with respect to ground potential, the plus terminal of the voltage source is connected to its minus terminal via a chain of resistors, with the resistors R2 and R6 being between the plus terminal and ground, while the resistors J? 11, R16, RVJ and RlS lie between earth and the negative terminal. In order to achieve voltage stabilization, the resistors R 11, R16 and RYl are bridged by two Zener diodes Z1 and Z 2. To adjust the bias on the control grid of the pentode V 2, which determines the capacitor current through the pentode V 2 , the resistor R16 is designed as a potentiometer, from whose movable tap a variable voltage can be taken.

So that the storage capacitor C can be charged up to a suitable voltage and the voltage source can then be switched off from the capacitor, a further charging control element Vl is provided, which is shown as a triode. The anode of the charging control element Vl is connected to the positive terminal via a resistor R 3; the anode is further connected through a diode Dl to the connection point between the resistor R4 and the diode D. 2 The diode Dl is arranged so that it leads current to the anode of the charging control process Vl . The cathode of the charging control process Vl is connected to the connection point between the Zener diodes Z1 and Z 2, and its control grid is connected via the resistor 227 and the diode D 5 to a transistor circuit, the transistor Tr and others. Includes switching elements that consist of resistors and - ■ diodes.

In order to be able to switch from a measuring position in which an adjustable, constant current flows through the discharge control element F 2 to a pulse position in which the storage capacitor C is first charged and then in the form of pulses via the discharge control element V 2 and the Patient is discharged, a switch S 2 is provided which is mechanically coupled to the above-mentioned switch 51, the closed position of the switch 52 corresponding to the measuring position and its closed position corresponding to the pulse position. The switch 51 is closed when the switch 52 is open.

In order to obtain the mentioned discharge pulses from the storage capacitor C , square-wave pulses from a pulse generator (not shown) with negative polarity are fed to the connection P. These pulses arrive at the base of the transistor Tr via the resistor R 12, and the transistor Tr is biased at its base by means of the resistors R 6 and R 9. The emitter of the transistor Tr is grounded; its collector is connected to the negative terminal of the voltage source via the resistor R 13, which represents the collector load , and the resistor RIS. The collector of the transistor Tr is connected to the control grid of the charging control process Vl via the resistor R7 .

Furthermore, the collector of the transistor Tr is connected to the movable tap of the potentiometer R 16 via a resistor R 15 and the diode D 4 . The diode D 5, which is connected to the control grid of the charging control element Vl , is connected with its cathode to a circuit which is connected at one end to a point between the resistors R 12 and i? Contains resistors R 14 and RlQ in series and the other end of which is connected to earth. The cathode junction of diode D 5, which is connected to a point between resistors R14 and RIO , is also connected to switch 52.

The circuit arrangement described operates in the following manner, it being initially assumed that switch 52 is in the measuring position, ie switch 52 is closed and switch 51 is open. In this case, the base of the transistor Tr is connected to a considerable negative voltage via the diode D 6, the resistor R 14 and the switch 52, and the base is biased so that the transistor Tr passes maximum current and a very low voltage drop between its emitter and collector. The collector of the transistor Tr is therefore essentially at ground potential. Since the switch 52 is closed, a circuit starting from the collector via the resistor R 7 and the diode to the low voltage at the soldering point at the connection point between the resistors RIl and RlS is closed. In this case the diode DS is conductive and a considerable voltage drop appears across the resistor R 7 due to the current flowing through it. The control grid of the charging control element Vl receives such a negative voltage with respect to the cathode of this charging control element that it is blocked. As a result, the diode Dl is blocked, since its cathode receives the voltage of the positive terminal via the resistor R 3, while its anode is at a lower voltage due to the voltage drop in the resistors R 1 and R 4. Furthermore, the diode D 4 is conductive in the connection from the collector via R15 to the movable tap of the potentiometer R 16, and since the diode D 4 has a low voltage drop, the control grid of the discharge control element V 2 receives a via the resistor R 8 Bias voltage which is essentially equal to the voltage at the movable tap of the potentiometer R 16. A current flows through the discharge control element V 2 from the anode to the earth, which, with a suitable selection and suitable working conditions of the pentode in a given area, is only slightly dependent on the anode voltage of the pentode.

The anode current of the pentode is obtained from the positive terminal via Rl, the instruments, the resistor R 4 and the diode D 2. If one assumes that the storage capacitor is not charged from the start, the capacitor is charged first. This charging takes place via the rectifier D 3 to earth and continues until the storage capacitor C has the same voltage as that which the anode of the discharge control element V 2 under comparable conditions when disconnected

5 6

Storage capacitor C. If the during the negative impulse to the connection

Charging of the storage capacitor C stops, P stops. This is achieved by then,

the instrument A shows the discharge - when the switch is in the impulse position-

Control organ in the prevailing setting of the, the control grid of the loading control process Vl

Potentiometer R 18 current flowing. · 5 essentially receives the voltage zero and thus

In the manner described below, a strong positive bias compared to the

from the display of the instrument A to the current cathode of the charging control element Vl, which is connected to the

be closed, the negative connection point between the Zener-

organ V2 is located when the storage diodes Zl and Z 2 are subsequently discharged. Hence it becomes a strong one

capacitor C flows. io anode current through the charge controller Vl

It is now assumed that the switches are flowing in, and the voltage drop at Vl will be in the pulse position, with switch 52 being small while the greater part of the span is open and switch 51 is closed, around the voltage drop between the plus terminal and short circuit earth to instrument A. In the indicated the resistor R 3 will arise. The diode Dl position, in which the switch S 2 is open, receives the 15 is connected with its anode to a low positive transistor Tr in the absence of a pulse at the voltage, and part of the current to the connection P receives such a bias through R 6 anode of the charge control process Vl is from the and jR9 that the transistor does not conduct any current. The positive terminal on Al, switch Sl, R4 and Dl success is that the collector hold a significant negative. Thus, the anode of the diode D 2 has a voltage with respect to the earth, which is connected to the control grid of the charge control diode D 2 via the 20 lower positive voltage than the cathode of the resistor R 7, which is connected to the storage capacitor Vl , which is blocked. It should be noted that generatorC is connected, which is blocked by a high voltage diode D 4 and it is charged with the low voltage. Thus, the diode D 2 is blocked tiven voltage of the movable tap of the potential and affects the discharge of the storage capacitor R 16 is not allowed to have an effect. 25 satorsC by the discharge control unit V 2 not.
. Since both the charging control element Vl and the As noted above, the storage capacitor discharge control element V 2 can be blocked, the gate C, when a pulse is present at the connection P storage capacitor C in the manner described, only via the body part to be tested will be discharged in a circuit from the positive terminal via the patient, which is between the connection resistor R 1, the switch 51 (which is the instruction points UT and B , because ment A before the possible powerful charging current of the rectifier D 3 between the storage capacitor), the resistor /? ^ the diode D 2, the capacitor C and ground is to allow the charging of the capacitor storage capacitor C and the rectifier D 3 to the sators, this rectifier ground charged. however, blocks the discharge current. At a den

If a pulse of sufficient negative amplitude stimulator is found, compound B is normal

tude at junction P, the base becomes a hand-held electrode while

of the transistor Tr, however, for the duration of this the electrode which supplies the current to the tooth on

Impulse so negative that the transistor Tr lei- the connection UT is connected.

will tend. The collector of the transistor takes the signal present at connection P.

approximately at ground potential, and in the same 40 during the intervals between the pulses one

Way, as described above, the control grid becomes such a base voltage that the same conditions

The voltage of the discharge control element V 2 is influenced, as described for the measuring position

from the tension on the movable tap of the.

Potentiometer R16, so that the working conditions The pulses fed to the connection P are received by the discharge control process V 2 from this control grid ^from a suitable pulse generator (not undervoltage and the constant acceleration shown), which are preferably determined with the shutter voltage that constant voltage tube V 3 is determined by the Konben system combined to form a unit. Since it is, if desired, devices are pre-anode current of an electron tube in the form of a, so that the connection P a pulse train pentode is not influenced within relatively wide limits by 50 or individual pulses each time the anode voltage is manually actuated, the control device is to be supplied by control devices ,
the tube when the storage capacitor C is discharged. In a practical embodiment of the current flowing in, when a conductive connection F i g. 1, a satisfactory operating mode exists between the connection points UT and B using the following components (the rectifier D 3 blocks the discharge current), 55 nents and working conditions:
practically completely predetermined, even for very different voltage values on the storage capacitor C Rl 4.7 kiloohms

and the impedance between the connection points- R2 is 220 kiloohms

ten UT and B (the tooth to be tested). Hence, R3 becomes 470 kilo ohms

the discharge current of the storage capacitor C in 60 R4 510 kiloohms

to a good approximation be the same as that of the instru- R 5 220 kiloohms

ment A was displayed in the measuring position, ahead of R 6 10 kiloohms

set that the setting of the potentiometer R 16 Rl 47 kiloohms

has not been adjusted in the meantime. R 8 1 kiloohm

In order to avoid that when the 65 R 9 discharges 22 kiloohms

Storage capacitor C another current from the R 10 100 kiloohms

Discharge controller V2 from the positive terminal via RU 60 kiloohms

the diode D 2 flows, this diode must be blocked, R 12 15 kiloohms

Claims (7)

7 8 R13 47 kilo ohms treating body part leading connection R14 100 kilo ohm devices (UT, B) a rectifier (D 3) R15 470 kilo ohms is arranged that the current-limiting discharge R16 47 kilo ohms charge control element (F 2) during the time period R17 30 kiloohms 5 of the control pulses an adjustable current conducts R18 4.7 kiloohms and during the intervening time interval C 0.1 microfarad valle is blocked and that the charging control device voltage between + and earth .. 320 volts from a direction of the Speic'herkonden- voltage between earth and - .. 140VoIt sators (C) conductive diode (D 2), which with the help of a locking device (Dl, Fl) through the Fig. 2 shows a modification of the apparatus- control pulses can be blocked. 1, in which the charging control element Fl instead of 2. Stimulation current device according to claim 1, characterized in that an electron tube in the form of a triode is a Tran- that is used to block the LadesistorTrl in the same way as the current-transmitting diode (D 2), whose anode triode works to pass a strong current through another diode (D 1) and let it charge as long as the pulse lasts, but to block the current connected to a voltage by the control element (Fl) in the pulse intervals. The bias is, which is equal to or smaller than the Kanung at the base of this transistor is given the method voltage of the discharge control element (F 2), through the transistor Tr of Fig. 1. Otherwise, and that the charge control element ( Fl) conductive, the starting position is the same as in F i g. 1. It should be noted in this way during the duration of the control pulses, but in this context, however, that the do not naturally pulse through an electron tube in the time intervals between the control transistor Tr. can be replaced, in which case the changes in the circuit configuration which are familiar to the specialist 3. electrical stimulation device according to claim 2, characterized in that an electronic auxiliary arrangement must be made. 25 control element (Tr) is influenced by the control pulse in such a way that it controls the control electrode. 1. Electromedical stimulation current device for pulse-blocked diode (D 4) on an adjustable Generation of current pulses with a patient voltage of 30 bar. ten circuit that consists of a series circuit 4. stimulation current device according to claim 3, characterized of a storage capacitor, connection device characterized in that the electronic auxiliary information on a part of the body to be treated and control organ (Tr) during the control pulse an electronic discharge control element on the control electrode of the charge control process (Fl) stands that with the help of control pulses the Ent- 35 gives such a voltage that a strong controls the charge of the storage capacitor, with current flowing through the charge control element (Fl), a voltage source that is used to charge the storage 5. Stimulation current device according to one of claims 1 cherk capacitor via an electronic charging to 4, characterized in that the discharge Control device, which with the help of the control control element (F 2) an electron tube in the form pulses during the discharge period of the 40 of a pentode. Storage capacitor is lockable between the 6. Stimulation current device according to one of claims 2 first control member and the storage capacitor to 5, characterized in that the charging is connected to the patient circuit, and control element (Fl) an electron tube in the form with a device for generating the control of a triode or transistor. pulses, characterized in that 45 7. stimulation current device according to one of claims 3 that in the charging circuit of the storage capacitor (C) to 6, characterized in that the auxiliary to him in series and parallel to the to the control organ (Tr) is a transistor. 1 sheet of drawings